Photovoltaic parameter extraction through an adaptive differential evolution algorithm with multiple linear regression

IF 7.2 1区计算机科学 Q1 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE

Applied Soft Computing Pub Date : 2025-04-11 DOI:10.1016/j.asoc.2025.113117

Bozhen Chen , Haibin Ouyang , Steven Li , Liqun Gao , Weiping Ding

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引用次数: 0

Abstract

Solar cells play a crucial role in generating clean, renewable energy. Accurate modeling of photovoltaic (PV) systems is essential for their development, and simulating their behaviors requires precise estimation of their parameters. However, many optimization methods exhibit high or unstable root mean square error (RMSE) due to local optima entrapment and parameter interdependence. To address these challenges, we propose MLR-DE, a novel hybrid approach that integrates adaptive differential evolution (DE) with multiple linear regression (MLR). The main innovation is to decompose the PV model into linear coefficients and non-linear functions, the latter being iteratively estimated using DE. By treating nonlinear function outputs as independent variables and known measured currents as dependent variables, linear coefficients are analytically solved through MLR. Additionally, we introduce a data-fusion-based parameter generation scheme to improve DE’s reliability by integrating historical crossover rates with estimated crossover rates. We validate MLR-DE through experiments across 11 PV configurations: 3 standard diode models and 8 environmental variants. The results demonstrate MLR-DE’s superiority in all tests. It achieves the lowest average RMSE compared to other algorithms, with standard deviations at or below 2e−16. In the Friedman test, MLR-DE ranked first with a score of 1.94, outperforming the second-place (3.72) and last-place (7.58) competitors. The convergence curve shows that MLR-DE achieves convergence in less than 3,000 function evaluations over standard models, with an average convergence time of less than 0.6 s.

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光伏参数提取采用多元线性回归自适应差分进化算法

太阳能电池在产生清洁、可再生能源方面起着至关重要的作用。光伏系统的精确建模对其发展至关重要，而模拟其行为需要对其参数进行精确估计。然而，由于局部最优陷阱和参数相互依赖，许多优化方法的均方根误差（RMSE）很高或不稳定。为了解决这些挑战，我们提出了一种新的混合方法MLR-DE，它将自适应差分进化（DE）与多元线性回归（MLR）相结合。主要创新点在于将PV模型分解为线性系数和非线性函数，非线性函数使用DE进行迭代估计，将非线性函数输出作为自变量，已知测量电流作为因变量，通过MLR解析求解线性系数。此外，我们引入了一种基于数据融合的参数生成方案，通过整合历史交叉率和估计交叉率来提高DE的可靠性。我们通过11种PV配置（3种标准二极管模型和8种环境变量）的实验验证了MLR-DE。结果表明MLR-DE在所有测试中都具有优越性。与其他算法相比，它实现了最低的平均RMSE，标准偏差等于或低于2e - 16。在Friedman测试中，MLR-DE以1.94分排名第一，超过了第二名（3.72）和最后一名（7.58）的竞争对手。收敛曲线显示，MLR-DE在标准模型上的函数评估次数小于3000次，平均收敛时间小于0.6 s。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Applied Soft Computing 工程技术-计算机：跨学科应用

CiteScore

15.80

自引率

6.90%

发文量

874

审稿时长

10.9 months

期刊介绍： Applied Soft Computing is an international journal promoting an integrated view of soft computing to solve real life problems.The focus is to publish the highest quality research in application and convergence of the areas of Fuzzy Logic, Neural Networks, Evolutionary Computing, Rough Sets and other similar techniques to address real world complexities. Applied Soft Computing is a rolling publication: articles are published as soon as the editor-in-chief has accepted them. Therefore, the web site will continuously be updated with new articles and the publication time will be short.